You are asked to solve a riddle. You are given the following pieces of information to help you.

1. I am a hyperbola centered at the origin.

2. My vertex is .

3. One of my foci is .

What is my equation?

### Guidance

In the previous concept, we graphed hyperbolas, given the equation. In this concept, we are going to work backwards and find the equation, given certain pieces of information. For this entire concept, the hyperbola will be centered at the origin.

#### Example A

Find the equation of the hyperbola, centered at the origin, with a vertex of and focus of .

**
Solution:
**
Because the vertex and focus are on the
-axis, we know that the transverse axis is horizontal. Therefore, the equation will be
. From the vertex, we know that
and
. Let’s solve for
using
.

The equation of the hyperbola is .

#### Example B

Find the equation of the hyperbola, centered at the origin, with an asymptote of and vertex of .

**
Solution:
**
We know that
, making the transverse axis is vertical and the general equation of the asymptote
. Therefore,
, making
. Therefore, the equation of the hyperbola is
.

In this example, we showed that the slope of the asymptote can be reduced to something that is not always , but , where is some constant that we can reduce the fraction by.

#### Example C

Find the equations of two hyperbolas with an asymptote of .

**
Solution:
**
This asymptote can be for either a vertical or horizontal hyperbola.
can also be a reduced fraction of
, like in the previous example. For example, the asymptote
reduces to
.

If the hyperbola is horizontal, then the equation of the asymptote is and that would make and and the equation would be . If the equation is vertical, then the asymptote is and and . The equation would be . If the slope is reduced from a larger fraction, we could also have or as a possible answer.

There are infinitely many hyperbolic equations with this asymptote.

**
Intro Problem Revisit
**
Because the vertex and focus are on the
-axis, we know that the transverse axis is vertical. Therefore, the equation will be
.

From the vertex and the focus, we know that and . Let’s solve for using .

Therefore, the equation of the hyperbola will be .

### Guided Practice

Find the equation of the hyperbolas, centered at the origin, with the given information.

1. vertex:

focus:

2. asymptote:

vertex:

3. Find the equations of two hyperbolas, centered at the origin, with different and values and an asymptote of .

#### Answers

1. The vertex is on the -axis, so this is a vertical hyperbola with . , so we need to find .

The equation of the hyperbola is .

2. Rewriting the slope of , we get . So, we know that and are in a ratio of 1:1. Because the vertex is , we know that and that the hyperbola is horizontal. Because and are in a ratio of 1:1, has to equal 4 as well. The equation of the hyperbola is .

3. One possibility is that and making the equation . A second possibility could be that and are a multiply of the ratio 4:3. So, and , making the equation .

### Practice

Find the equation of the hyperbola, centered at the origin, given the information below.

- vertex: , focus:
- vertex: , focus:
- , focus:
- vertex: , asymptote:
- , focus:
- vertex: , asymptote:
- asymptote: , vertex:
- asymptote: , , vertical transverse axis
- vertex: , focus:
- Find the equation of two hyperbolas such that they have the same and values, the equation of an asymptote is , and centered at the origin.
- Find the equation of two hyperbolas such that they have different and values, both horizontal, the equation of an asymptote is , and centered at the origin.
- Find the equation of two hyperbolas such that they have different and values, both vertical, the equation of an asymptote is , and centered at the origin.
- Find the equation of two hyperbolas such that they have the same and values, the equation of an asymptote is , and centered at the origin.

Find the equation of the hyperbolas below.